Cationic unsaturated amine-functional silane coupling agents

ABSTRACT

ORGANOSILICON COMPOUNDS OF THE FORMULA   (*SI-Q-N(+)(-R&#39;&#39;M)-Z-C(-R&#34;)=CH2) Y(-) IN WHICH   Q IS A DIAVALENT HYDROCARBON RADICAL OR A DIVALENT HYDROCARBON RADICAL CONTAINING OXYGEN IN THE FORM OF   -CO-C-, -COO-C-, -CO-, OR &gt;C(-OH)-   GROUPS OR NITROGEN IN THE FORM OF   &gt;N-R&#34;   GROUPS, Z IS A DIVALENT ORGANIC RADICAL HAVING A DOUBLE BOND CONJUGATED WITH THE   -C(-R&#34;)=CH2   AS COUPLING AGENTS FOR PROMOTING THE ADHESION OF ORGANIC POLYMERS TO SOLID INORGANIC SURFACES.   CH=C(-CH3)-CH=CH2) BR(-)   ((C3H7-O)3-SI-(CH2)2-(1,4-PHENYLENE)-N(+)(-CH3)2-CH2-   MOIETY, Z BEING BONDED TO THE NITROGEN ATOM BY A C-N BOND, R&#39;&#39; IS INDEPENDENTLY SELECTED FROM THE GROUP CONSISTING OF THE HYDROGEN ATOM, LOWER ALKYL RADICAL ORR A HETEROCYCLIC ORGANIC COMPOUND CONTAINING THE NITROGEN ATOM AS A RING MEMBER, M IS AN INTEGGER OF 1 ORR 2, R&#34; IS THE HYDROGEN ATOM OR A LOWER ALKYL RADICAL, AND Y IS AN ACID ANION, ARE DISCLOSED. THE COMPOUNDS, FOR EXAMPLE

United States Patent i ABSTRACT OF THE DISCLOSURE Organosilicon compounds of the formula o e ESi-Q,NZC=OH2 Y, in Whlch R...v R"

Q is a divalent hydrocarbon radical or a divalent hydrocarbon radical containing oxygen in the form of groups or nitrogen in the form of groups; Z is a divalent organic radical having a double bond conjugated with the --C-'- CHz 3,734,763 Patented May 22, 1973 Thus, it is an object of the invention to provide novel cationic organosilicon compounds which have utility as coupling agents.

It is another object of the invention to provide high strength articles made from vinylic polymers and siliceous reinforcing materials.

The compositions of the invention have the general formula 69 9 X Si-QNZC=CH2 Y film RI! and partial condensate thereof, in which V X is the hydroxy group or a hydrolyzable radical;

moie'ty, Z being bonded to the nitrogen atom by a C--N bond;

R is independently selected from the group consisting of the hydrogen atom, lower alkyl radical or a heterocyclic organic compound containing the nitrogen atom as a ring member;

m is an integer of 1 or 2; v

R" is the hydrogen atom or a. lower alkyl radical; and

Y is an acid anion; are disclosed. t l

The compounds, for example as coupling agents for promoting the adhesion of organic polymers to solid inorganic surfaces.

This application is a continuation-in-part of j'appli'cation Ser. No. 825,035, filed May 15, 1969, now abandoned.

Organosilicon compounds having amino substituents have attained considerable commercial success as coupling agents to improve the adhesion of certain polymeric materials to siliceous substrates. A'minopropyl-substituted silanes are representative of the organosilicon compounds utilized in such bonding applications in conjunction with phenolic and melamine type resins. Ethylenically unsaturated silanes, such as vinyltrichlorosilane, are used in these applications when bonding with vinylic polymers. To date, the amine-functional silanes have not been used as the sole component of coupling agents for vinylic polymers.

It has been found that the compositions claimed herein provide excellent adhesion of organic polymers to siliceous surfaces, for example, when the unsaturated amine-functional silanes of the invention are applied in their cationic form to siliceous reinforcing surfaces the adhesion of vinylic polymers to the surface is greatly improved. The compositions of the invention can also be used as a sizing on glass fibers to minimize the build-up of static charge on the fibers.

R is a lower alkyl radical; Q is a divalent hydrocarbon radical or a divalent hydrocarbon radical containing oxygen in the form of groups or nitrogen in the form of R is independently selected from the group consisting of the hydrogen atom, a lower alkyl radical or a heterocyclic organic compound containing the nitrogen atom as a ring member;

In is an integer of l or 2;

Z is a divalent organic radical having a double bond conjugated with the --O=CH2 RI! moiety, Z is being bonded to the nitrogen atom by a CN bond; R" is the hydrogen atom or a lower alkyl radical;

n is an integer having a value of from 1 to 3 inclusive; and Y is an acid anion.

As described above, X is the hydroxyl group or a hydrolyzable radical, such as alkoxy radicals, for example, methoxy, ethoxy, isopropoxy, butoxy and isobutoxy; aryloxy radicals, for example, phenoxy; halogen atoms, for example, chlorine, bromine and fluorine; acyloxy radicals,

for example, acetoxy, propionoxy and decanoxy; ketoxime radicals, for example, (CH C=NO; and amine radicals for example, CH NH, NH and (C H N. As used herein hydrolyzable group is taken to mean any radical which will react with water at room temperature to form a silanol.

R is a lower alkyl radical containing no more than 6 carbon atoms, for example, methyl, ethyl, isopropyl, butyl or a hexyl radical. The same or different R substituents can be attached to the same silicon atom.

For purposes of this invention, the linking group, Q, between the silicon atom and the nitrogen atom, is composed of carbon, hydrogen and oxygen, the latter being in the form'of carbonyl, ether, ester and hydroxyl groups or nitrogen in the form of an amine group. Specific examples of Q are divalent hydrocarbon radicals such as the propylene radical, the (CHz-)e radical, the

-CHzCCHz carbonyl groups such as O .C 1. \CHrr/a COHZCHP,

ether radicals such as 3 CH CH CH OCH CH CH and CH CH CH OCI-I CH OCH CH; ester groups such as R is independently selected from the group consisting of the hydrogen atom, a lower alkyl radical such as described with respect to R or heterocyclic organic compound containing the nitrogen atom as a ring member, for example,

it It l l on; om on: om HO/ on and on Of course when R is such a heterocyclic compound, m is equal to 1, whereas when R is a hydrogen or lower alkyl radical, m is equal to 2.

Z is a divalent organic radical composed of carbon, hydrogen and oxygen such as described with respect to the Q radical, further characterized as having a double bond conjugated with the vinylic moiety. Z is bonded to the nitro- 50 gen by a carbon-nitrogen bond. Illustrative of such divalent radicals are arylene radicals, such as the phenylene, biphenylene,

radicals; carbonyl radicals, for example and vinylic groups, such as and R is the hydrogen atom or a lower alkyl radical such as described with respect to R.

Ha C2H5 G CHzCOO I G) 9 (CHaO) Si(CH2) aNOHzCHaNHCHzCHz-O-C-CH=C Hz Cl CHO s /CH\ i? on CH CH-CH e 3 )ZJJ T 2 2 2 and Partial condensates of the cationic unsaturated aminefunctional silanes are also within the scope of the invention. Partial condensate is meant to imply that a detectable amount of the hydroxyl orhydrolyzable groups remain uncondensed in the compositions, preferably at least one such group per every four silicon atoms remains uncondensed. The partial condensate is a polymer of -SiOSiO units with the silicon atoms retaining their cationic functionality and the requisite amount of hydroxyl groups, the hydroxyl or hydrolyzable groups being available to form bonds with inorganic substrates when the polymer is used as a coupling agent or primer.

The compounds of the invention can be prepared by reaction of a conjugated unsaturated alkylhalide with an amino-functional silane. This reaction is carried out in a suitable solvent, with conditions of time and temperature varying widely. A second method of preparation, analogous to the first, is the reaction of silyl-substituted alkylhalide with a conjugated unsaturated aliphatic amine to produce the cationic compounds. Both of these reactions are carried out in a suitable solvent, such as dimethylformamide, l-methoxy-2-propanol, 1-2 dimethoxyethane, tert butyl alcohol, isopropanol, methanol and diacetone alcohol. Certain of the cationic compounds are obtained by dissolving the nuetral unsaturated secondary and tertiary amine in an acid solution, such as dilute surfuric acid. These methods of producing the compounds are illustrated in detail in the examples.

, The cationic unsaturated amine-functional silanes are soluble in aqueous media to the extent that at least 5 weight percent solutions are readily formed. These solutions can be applied to solid inorganic materials by conventional techniques such as dipping, brushing or spraying. The solid inorganic material treated in this manner then has attached to its surfaces the hydrolyzate of the formula G9 9 {OS1-Q,lTT-Z-C=CH2} R... R" in which all radicals are as previously defined.

This hydrolyzate may be in the form of a partial condensate in which a detectable amount of hydrozyl or hydrolyzable groups (preferably at least one such group per every four silicon atoms) remain uncondensed and are than available for reaction with sites on the inorganic surface to provide chemical bonding. Although not wishing to be bound by theory, it is believed that the ESiOH radicals in the coupling agent react with silicon-bonded hydroxyl groups on siliceous surfaces or with metal oxides on metal surfaces to form the chemical bond. Contrary to this theory, and thus unexpectedly, certain amine hydrochlorides of the invention provide increased adhesion between vinylic polymers, such as acrylates and gold, a metal which is not subject to oxidation.

Cationic treated siliceous materials can be combined with organic resins, such as polyesterstyrene resins, to provide reinforced articles. Superior strength is imparted to these articles because the interface of the resin and the siliceous material is formed by reaction of the organic polymer and cationic compound in one instance and the reaction of ESlX groups and water on the solid in the other instance. It is believed that the enhanced properties of such a composite are, at least in part, provided by an ordering or alignment of molecules at the interface which is a result of their cationic nature.

Organic polymers include thermoplastic and thermosetting polymeric materials, both of the condensation type, such as the polyamides and the vinylic type, such as the polyolefins. Representative of condensation polymers are the acetal polymers, such as made by the copolymerization of propylene oxide and formaldehyde; alkyd resins, such as are synthesized by reacting a saturated polybasic acid with a polyol; amino resins, such as the reaction products of urea or melamine with formaldehyde; epoxy resins, such as those derived from bisphenol A and epichlorohydrin; phenolic resins, both resols and novolaks; polyamides, such as the reaction product of hexarnethylene diamine and adipic acid; polycarbonates, such as the reaction products of bisphenol A and a carbonate diester; polyester resins, such as poly(ethylene terephthalate) and polysulfone resins, such as those made by the reaction of the disodium salt of bisphenol A and 4,4'-dichlorodiphenylsulfone. The aliphatically unsaturated monomers suitable for polymerization and fabrication of the abovedescribed reinforced composite include styrene, acrylonitrilebutadiene-styrene, acrylonitrile-styrene, isobutene, styrene-butadiene, ethylene, propylene, vinylacetal, vinylchloride-vinylidene, methylmethacrylate, and ethylenepropylene-cyclohexadiene. The polymers, formed by polymerization of the aliphatically unsaturated carboncarbon bonds, can be rigid materials, such as polyester resins or elastomeric materials, such as styrene-butadiene rubber, and as a class are conveniently designated as vinylic polymers. When vinylic polymers are used in combination with unsaturated amines of the invention, especially the amine hydrochlorides, it may be desirable to add a free radical initiator to promote reaction between the polymer and the unsaturation of the amine. The free radical source should be one which is active at the bonding temperature, thus, dicumyl peroxide is preferred for use with polypropylene, and benzoyl peroxide is preferred for use with styrene-containing polymers.

Solid siliceous materials commonly used for reinforcing organic polymers include glass, in the form of cloth, strands and chopped fibers; silica, asbestos, mica, talc, and quartz. An additional advantage is realized when fibrous materials are treated since the cationic compounds minimize the build-up of static charge in the fibers and thereby facilitate the handling of strands, rovings and the like.

As an alternative to treating the solid reinforcing material and then forming the composite, the cationic compounds of the invention can be copolymerized with the unsaturated monomers, such as methylmethacrylate, styrene and vinyl acetate, to form a vinylic polymer which in turn can be combined with untreated reinforcing material to form the composite. Generally the copolymers of the invention contain from 0.5 to 5 mol percent of the cationic amine-functional units. The copolymers are produced by vinylic polymerization with conventional catalysts by emulsion polymerization, solution polymerization and other methods which are well known for polymerization of the particular monomer. Of course, the vinylic polymers must be in such a physical state (i.e.; softened or melted) that the untreated rein-forcing material can be incorporated therein or laminated thereto.

Also, within the scope of the invention is the formation of the cationic coupling agents in situ during production of composite articles. This can be accomplished by coating the substrate or reinforcing material with one reactant necessary to the formation of the cationic compound and coating the solid vinylic polymer with the other reactant. For example, when polyethylene film is dipped in a solution of vinylbenzyl chloride and then pressed at temperatures of about 200 C. onto aluminum panels primed with n beta (aminoethyl) gamma aminopropyltrimethoxysilane, a strong bond between the aluminum and polyethylene is obtained.

In addition to their utility as coupling agents on siliceous reinforcing materials, the cationic compositions of the invention are primers for bonding other inorganic solids, for example metals, such as aluminum, magnesium, zinc, tin, chromium, titanium or steel to the organic polymers. The alkaline minerals are another class of inorganic solids useful in the formation of composite articles. Polyester castings utilizing an amine hydrochloride coupling agent and filled with granular calcium phosphate show much greater flexural strength than the same type of casting in which the coupling agent was omitted. Calcium phosphate is one of the principal components of tooth enamel, thus the amine hydrochlorides have utility as adhesive aids in dental restorations.

The amine hydrochlorides of the invention (wherein at least one R radical is a hydrogen atom) are especially useful as primers for increasing the adhesion of vinylic polymers to gold. This is unexpected since gold does not oxidize, and it is generally thought that an oxidized or hydroxylated surface is necessary to obtain good bonding. Good adhesion of vinylic polymers, such as the acrylic resins, to gold surfaces is of special importance in the fabrication of dental restorative prosthetic devices.

The copolymeric cationic materials of the invention also exhibit the increase in bond strength. For example, when copolymerized with acrylic esters, the cationic acrylate forms a thin hard film, which when cured, adheres tenaciously to common structural material, such as steel or ceramic surfaces. The copolymers can be pigmented and used as paint compositions.

The following examples are illustrative of the invention, which is properly delineated in the appended claims.

EXAMPLE 1 A mixture of 50 grams of 3-chloropropyltrimethoxysilane (0.25 mol), 0.5 gram of methyliodide, 50 grams of 2-(dimethylamino)ethyl methacrylate (0.32 mol), 100 grams of dimethylformamide and 0.5 gram of sulfur was maintained at C. for 24 hours, after which time titration showed 0.21 equivalent of halide ion present. After a total of 50 hours heating at 95 C., titration showed 0.25 equivalent of halide ion present and the reaction was considered complete. The product,

ON O: H SO EO N ON EEO mQEQOXQEQ E x movz mo mooomo mo -2 N NO J EO E N Oo momo Eo OH A59z mo mofiomxo mov 2 6Eo Mo E0 O O OO 8 2 NJ mz mo momzmov@859 3 GENTAMV MO EO H OO m H N N mzfio mo mowxo m ov 2 65o fio fio OO O: H EO BO N 2 OH qmovmz mo mofioaxo mov ---NH m mo gaxofiov N OO E EO E N H O N QEOOOMZEOEQQooEwoOo Eo 6Eo Mu fio N OOH 4 fi O N qmovzfiofio moaxofiov OH OH ONH E OEOO EO EZE B E E 2 do mo mooooqmovo mo ON 25825050505"8E8 O 65o fiofio5xofi9 H OOH -JE B EEQO O N movz mo moooofl movo fio ---N ON OO 1 3 235 5 2 flo momxo mov OH x movz mofiooooqmovo mo dmo @lmzofiov w ON 3 N N x movzfiofiooooA movo Eo ---O EEQ QV E SEOO OO OO EO E E NA O N zfiovz mo mooooQmoOo mo N flofio @lwxo mov H OO p z sfifi m O N x movzaosmoOOOEMOVO EO v ON O: 2 ON Oo moamoxflo mov 3 s movzio mooooamovo fio n ON O: J N EN A E flo moamozmflofiov ON 2E9zfiofiooooemovo mo N OO NO 2 835 5 OO 625862059 Ow emovzfioiooooQmoOo mo 4 2:: 40 5 3 m 6 3 k 8 NENEPH QOEOOQEOU 25B 8 2 4 35054 335360 358M 5 4 H mqmfla as 5 3: EN 32558 EN N ONO 3305 on 8 now 0215 Ho 3:096 2383: 05 mo @mm 3N2 N NO uoum u an: 252% 6 3 Compositions 1-11, 15 and'16 are quaternary ammonium'halides', while compositions 12, 13 and 14 are hydrochlorides of secondary and tertiary, amines. Compositions 15 and 16 are not within the scope of the invention-they have isolated terminal saturation and were produced for 100 C. to. form molded sheets having a thickness of about 120 mils and containing about 30 percent by Weight of the cured polyester resin. The resin utilized in the laminates was a solution of70 parts linear polyester in 30 parts styrene monomer, to which was added 0.5 part comparison as coupling agents. Those products within the benzoyl peroxide dissolved in about 7.5 parts of styrene scope of the invention (1-14) have terminal unsaturation monomer. The linear polyester in the resin mixture was which is activated by conjugation with double bonds or prepared from phthalic acid and maleic acid in equimolar aroamtic rings. All of the products formed cationic disperproportions reacted with polypropylene glycol, the 70 sions in water. percent solution of this polyester in styrene having an EXAMPLE 2 acid number of about 35.

The flexural strengths of the laminates were determined Heat-cleaned 181 (Style E) glass cloth was dipped into in accordance with US. Federal Specification L-P 406b 0.2% aqueous dispersions of the reaction mixtures of Method 1031. Flexural strength was also determined on Example 1 (which were 50% solvent) providing a 0.1% samples of the laminates which had been immersed in concentration of the cationic coupling agent. The treated boiling water for 2 hours and then wiped dry, this being glass cloth was air-dried for one hour and then heated for a test which is recognized as roughly the equivalent of 7 minutes at 100 C. The glass cloth treated with amine standing in water at room temperature for one month. hydrochlorides (compositions 12 and 14) was rinsed in a The results of the latter test will be referred to hereafter 1% aqueous ammonia solution before drying. 20 as the 2-hour boil data. The 2-hour boil fiexural strength Laminates, which contained 14 plies of the treated glass multiplied by 100 and divided the strength of the laminate cloth (laid up with the. warp rotated 90 in alternate as molded is reported as the percent retention of lamiplies) impregnated with a polyester resin, were prepared. nate strength. The following results were obtained on the The laminates were cured for minutes at 30 psi. and above'prepared laminates.

' TABLE II Laminate properties Flexural strength (p.s.i.)

Percent Formula of coupling agent on glass cloth Dry 2 hr. boil retention Composition ,9

1 (C1130) SiCHQOHQCHzNWH hCH OHQOCOG(OH3)=CH; c1 90, 300 79, 200 88 ea e 2; (CHaOhSKCHa) CH7N(CH3)2CH:CH2OCOC(CH3)=CH2 01 51,500 18,500 36 ea t r e 3 CHaOSi(CHa)2CHzN(CHa)zCHzCHzOCOC(CH )=CH2 I Q1 59,400 32,400

4.-.. c1130 asronm omnomomoooo ona=om 01 86,300 80,000 03 s e e 5..;.;-.--.- (CH3Q)3S1:- QH2N(CH3)2CH2CH2OCOC(CH3)=CE5 Bl 78,600 75,000 00 e e 2.. (CHsO)aSiC'H2CH2CH2N(CH3)ZCHzCHzO'COC(CH3);CH2 I 7 75,900 75,000

. N w, e 7..... (CH O)a SiCHzN(CH )2CH7CHOCOC(CH )=CH2 Cl 84,000 79,000

- o e 3 )3 H2CHz7-'CH2N(CHs)2CHzCHzOC0C(CH3)=CH2 01 71,200 71,300 100 a I "ea e 9.-'.'-'.-'.'.'.'.'.'-'.";...' (CHQ)aSiCH2CH2CH2N(CH3) 2CH2CH2OCOC(CH3)=CH2 Cl Y Y e v i e 1:. (CHzOhSiOHzCHiCHgNwHahCHr-OH=OH0 01 86,300 80,000 93 GB I :1 e 11 I )SSi@CHZNH(t-C4HB)CH2CH2QQQO(QH:Q=OH2 Br 79,000 04,200 81 9 p G 12*-- (CH Q) SiCH2CH2CH2NH(CH3) CHz-. CH=CH2 01 91,200 86,700 95 13.. (C2H50 3S1CH2OH2OH2NH2CHP CH=CH3 Cl 89,000 78,100 89 '27. (CHaO) S1(CH2)3NCH2CHzNH2QHr-@CH5 CH ()1 87,000 80,700 93 6B 9 15.--;." (CH3O)3S1CH2CH2CH2N(CH3)2CH2CH=CH2 C1 23,400 10,200 43 16 (CH O) SiCH2CH2CH2N(CH3)2CH2CH2OCH=CH C1 33,100 18,500 50 Controlmi No coupling agent on glass 38, 700 12, 300 32 Treated glass was rinsed in dilute a'queous'ammonia solution.

The above data demonstrates that the cationic compositions of the invention are highly eflective coupling agents; especially whencompared with cationic agents,

the conjugation necessary for activation of the double bond. Because of their stronger bond to the glass, the compounds which have three hydrolyzable groups atsuch as-compositions 15 and 16 Which do not contain tached to the silicon are preferred. Compositions where 11 n is 1 or 2, as in compositions 2 and 3, are effective but to a limited extent when compared with the compositions where n is 3.

EXAMPLE 3 A mixture of 18.7 grams (0.1 mol) of (CH O) SiCH CH CH N(CH 9 grams of methacrylic acid, 10 grams of epichlorohydrin in 40 grams of t-butyl alcohol and 0.1 gram of sulfur (as stabilizer) was refluxed for 3 hours. Titration indicated the presence of 0.1 mol equivalent of chloride ion. The product was H CH3 & e (CHICDBSICHZOHICHZNCHI HCH2OC- CHz Cl Ten milliliters of the reaction mixture was mixed with 250 milliliters of 1-2-dimethoxyethane to precipitate a granular solid. This solid was separated by filtration and dried to recover grams of the pure product. The solid was soluble in water and titrated for an equivalent weight of 9 9 370/01; theory=365/Ol.

Glass cloth, treated with an 0.1% aqueous solution of the above product was laminated with polyester resin and tested for flexural strength in the same manner as described in Example 2. Results are tabulated below:

Flexural strength p.s.i. 75,400

2-hour boil p.s.i. 63,300

Percent retention percent 84 EXAMPLE 4 A mixture of 14 grams (0.1 mol) of glycidyl methacrylate and 17 grams (0.1 mol) of was allowed to stand at room temperature. After 24 hours the product was a clear viscous oil which did not contain any epoxy or free secondary amine. Gasliquid chromatography indicated that there was no unreacted starting material in the product. Infrared spectroscopy identified the methacrylate double bond and was consistent with the following proposed structure:

a r (CHsO)aSiCHaCHzOHrN-CHCHCHzO C-C=C l A second nonionic agent was prepared by allowing a mixture of (C H O) SiCH CH CH NH and 1-3-butylene dimethacrylate to react at room temperature. After 2 hours the material had reacted to form the two isomers:

In addition, the reaction mixture contained an equivalent amount of the bis-adduct and a small amount of unreacted butylene dimethacrylate.

A third nonionic agent was prepared by reacting a mixture of 25 grams of (cmonsicmonionzoomcfi crn and 18 grams of CH =C(CH )COOCH CH NH(t-butyl) with 1 gram tris(dimethylaminoethyl) phenol catalyst and 0.2 gram of sulfur stabilizer at 100 C. for 8 hours. The amber oily product contained only a trace of starting materials and retained the methacrylate double bond as identified by its infra-red spectrum. The product was insoluble in water, but soluble in 50% aqueous acetone or dilute aqueous hydrochloric acid.

A portion of the above products were converted to their cationic form by addition of dilute aqueous hydrochloric acid. The remaining portions of the products were added to dilute aqueous acetone solutions to form a non-ionic treating formulation. Glass microscope slides were treated by soaking for 15 minutes in the hydrochloric or acetone solutions and drying for 30 minutes at room temperature. The polyester resin described in Example 2 was applied to the'glass slides and cured for one hour at 100 C. Adhesion of the cured polyester to the treated slides was tested qualitatively by attempting removal of the resin with a razor blade after initial cure and after 3 days immersion in water.

The cationic form (chlorides) proved to be very good coupling agents-the resin adhering strongly to the glass, even after 3 days in water-while the nonionic form of the products (applied from acetone) gave only limited increase in adhesion which was lost after immersion in water.

EXAMPLE 5 The importance of the cationic nature of the compounds of the invention is illustrated by the following: The compound z )aSiCH2C 2CHaN(CI-Ia) CH2CH(OH) CHzO C C (CH;)==CH1 prepared as described in Example 4, was applied to glass cloth from isopropanol-water, dilute aqueous acetic acid and dilute aqueous hydrochloric acid. The cloth was laminated with polyester resin and tested as previously described. The cationic nature of the amine increases in the order given below:

Laminate properties Flexural strength Solution of amine-functional sllene Percent coupling agent Dry 2 hr. boil retention 0.1% isopropanol-water 55, 200 30, 000 54 0.5% isopropanol-water..- 74, 300 49, 500 67 0.1% dilute acetic acid 77, 000 63, 600 88 0.1% dilute hydrochloric acid 80,400 62, 500 78 It can be seen that the cationic agents were superior to the same compound applied from the non-ionic isopropanol-water: solution. A five-fold increase of coupling agent in the isopropanol-water solution did not give improvement equivalent to the weaker of the two cationic forms, the acetate salt. Comparison of wet strength retention of the laminates also demonstrates the superiority of the cationic form.

EXAMPLE 6 When 2-3 mole percent of is copolymerized with -99 mol percent of a mixture of ethylacrylate, methylmethacrylate me 40% solution in Cellosolve acetate, there is obtained a clear acrylic copolymer, which when filmed on metal surfaces and baked at 150 C. is converted to a clear, hard coatingwith improved adhesion and'solvent resistance.

EXAMPLE 8 cH o),si cn ,oocc(ou, =cn

Results are as follows: 7 l I Coupling agent Logr wmoas to eigcmcm oorr The lower log value obtained byuse of the cationic composition signifies the better charge dissipation which facilitates handling of the glass fibers.

EXAMPLE 9 Composite articles of wollastonite filled polypropylene were prepared by injection molding. The molding composition was prepared by mixing 100 parts by weight of wollastonite with 0.5 weight percent of an amine hydrochloride coupling agent (Composition No. 14 of Example 1) in a Waring Blendor for one minute. The wollastonite was then mixed with 150 parts by weight of commercially available powdered polypropylene. In certain instances, weight percent of vinylic monomer and one weight percent of dicumyl peroxide (catalyst) were added to form in situ a cationic amine functional copolymer as the coupling agent. The injection molding apparatus was operated on a 45-second cycle at an injection pressure of 600 p.s.i. at the following temperatures: rear heater, 430 F.; front heater, 470 F.; and mold; 120 F. Flex and tensile bars were molded and tested. The table relates the coupling agents used to the test results. The recorded data are the average of five test results.

Strength (p .s.i.)

These data demonstrate the supeiror strengths obtained by use of the cationic amine functional coupling agents of the invention.

EXAMPLE Clean aluminum panels were wiped with a 10 percent solution of the reaction product of beta-aminoethylgamma-aminopropyltriethoxysilane and vinylbenzyl chloride in 2-methoxyethanol. The primed panels were air dried for five minutes and then pressed against molten polymers of various chemical structure. The bonding conditions for the different polymers are noted below. All of the polymers are commercially available materials.

14 After cooling to room temperature, adhesion was determined qualitatively by loosening a portion of the polymeric film with a razor blade and pulling. Adhesion was 'considered'nil'when the film detached from thepanel without pulling and excellent when there was cohesive failure or the film could not be pulled from the panel. Adhesion of the different polymeric films is listed below:

TABLE III Bonding conditions Temp. Polymer (C.) Time Adhesion Polypropylene hylene Poly(styrene'aerylonitri1e) Poly(acrylonitrile-butadiene styrene) Styrene-butadiene elastomer Polyiormal Saturated polyester (Mylar) Polysulf Poly (chlorotrlfiuoroethylene) NOTE! C.F.indicatescohesive failure.

These data demonstrate that the coupling agents of the invention are effective with a wide variety of polymers including condensation polymers, such as polycarbonate, and vinylic polymers, such as polystyrene.

EXAMPLE 11 The coupling agent utilized in Example 10 was used to increase the adhesion of molten polyethylene in a variety of substrates. Each substrate was primed with the coupling agent solution described in Example 10. High density polyethylene was then bonded to the primed surfaces by pressing lightly under the conditions indicated. For purposes of comparison, adhesion of polyethylene ,bonded under the same conditions to unprimed surfaces was also determined. Results are as follows:

C.F. indicates cohesive failure.

These data demonstrate that the adhesion of vinylic polymers to a variety of inorganic substrates, both siliceous and nonsiliceous, is improved by use of the coupling agents of the invention.

EXAMPLE 12 Bonding in accordance with the present invention was accomplished by the in situ formation of amine hydrochlorides. Glass microscope slides were primed with a 10 percent solution of an amine-functional silane. The solvent was Z-methoxyethanol. Granules of a commercially available polypropylene (Profax 2303 from Hercules Incorporated, Wilmington, Del. were primed with a 10:1 mixture of vinylbenzyl chloride and dicumylperoxide diluted to 10 percent reactive ingredients with Z-methoxyethanol. The treated granules were pressed onto the treated slides for one minute at 250 C., cooled to room temperature and examined for adhesion. For purposes of comparison, the adhesion of untreated polypropylene granules bonded to treated glass slides was also determined. Results are given below:

Adhesion to glass of- Untreated Treated Silane on glass polymer polymer None Nil Nil. (C2HsO)3SiCH2CH2CHaNHr... Very poor- Good. (CH30)3Si(CH2)3NHCH2CH2NH2 d cltlll tllslvfi a1 ure.

These results show that the amine hydrochloride was formed in situ and did increase adhesion of the polymer to the glass.

EXAMPLE 13 Adhesion promotion of vinylic resins to alkaline minerals was demonstrated by preparing castings from a mixture of powdered alkaline mineral fillers and a commercially available unsaturated polyester resin. The coupling agent was added to the resin in an amount equivalent to 0.5% by Weight based on the weight of filler. Filler content and composition and flex strengths of the cured castings are given below:

Flex strength (p.s.i.) of castings filled with- 43% magnesium Coupling agent 48% 021603 43% Ca (PO4): silicate None 9, 970 4, 600 10, 600 Composition No. 14

of Example 2 11, 700 9, 290 12, 370

EXAMPLE 14 showed fairly good dry adhesion to the'unprimed gold,

being removed only with difiiculty, but after soaking in water for eight hours the resin detached of its own accord from the gold. Adhesion of the cured resin to the primed gold was excellentthere was cohesive failure of the resin during attempts to remove it from the primed surface. After soaking in water for three days, attempts to remove the resin from the primed gold surface again resulted in cohesive failure in the resin.

That which is claimed is:

1. An article of manufacture comprising a solid inorganic substrate having coated on the surface thereof a composition of the formula Il a n Im II and partial condensates thereof, in which,

X is the hydroxyl group or a hydrolyzable radical; R is a lower alkyl radical;

n is an integer having a value of from 1 to 3 inclusive;

Q is a divalent hydrocarbon radical or a divalent hydrocarbon radical containing oxygen in the form of -o o-, -o o 0-, o-

- J OH groups or nitrogen in the form of 16 v R is independently selected from the group consisting of the hydrogen atom, a lower alkyl radical or. a heterocyclic organic compound containing the nitrogen atom as a ring member; m is an integer of l or 2; Z is an arylene radical having a double bond conjugated with the 1 -C=CHg moiety, Z being bonded to the nitrogen atom by a C-N bond;

R" is the hydrogen atom or a lower alkyl radicakand Y is an acid anion.

2. An article in accordance with claim 1 where, in the composition, It is equal to 3, m has a value of 2 and R- is selected from the group consisting of the hydrogen atom and loweralkyl radicals. H 7

3. An article in accordance with claim 2 wherein the solid substrate is fibrous glass.

4. An article in accordance with claim 1 where, in the composition, Z is a radical.

5. An article in accordance with claim 4 wherein a composition of the formula is bonded to the fibrous glass.

6. An article in accordance with claim 4 wherein a composition of the formula is bonded to the fibrous glass.

7. An article in accordance with claim 1 wherein the solid substrate is metal.

8. An article in accordance with claim 7 wherein the metal is gold and a composition of the formula is bonded to the surface thereof.

9. A composite article comprising an organic polymer bonded to a solid inorganic reinforcing material, the surface of the inorganic material having been coated prior to bonding with a composition of the formula groups or nitrogen in the form of groups; R' is independently selected from the group consisting of the hydrogen atoms, a lower alkyl radical or a heterocyclic organic compound containing the nitrogen atom as a ring member;

m is an integer of 1 or 2;

Z is an arylene radical having,a double bond conjugated with the -C=CH:

moiety, Z being bonded to the nitrogen atom by a CN bond;

R" is the hydrogen atom or a lower alkyl radical; and

Y is an acid anion.

10. The article of claim 9 wherein the organic polymer is a vinylic polymer and the inorganic material is a siliceous solid.

11. The article of claim 10 wherein the siliceous solid is fibrous glass.

12. An article in accordance with claim 9, where in the composition, Z is a radical.

13. An article in accordance with claim 12 wherein the siliceous solid is fibrous glass.

14. An article in accordance with claim 13 wherein a composition of the formula has been bonded to the fibrous glass.

15. An article in accordance with claim 13 wherein a composition of the formula has been bonded to the fibrous glass.

16. An article in accordance with claim 9 wherein the organic polymer is a vinylic polymer and the inorganic material is calcium phosphate, a composition of the formula having been bonded to the calcium phosphate.

References Cited WILLIAM D. MARTIN, Primary Examiner W. H. SCHMIDT, Assistant Examiner US. Cl. X.R.

l17-75, 124 F, 126 AB, 126 GS, GN, 135.1; 260448.2 B, N 

